JP6666988B1 - Light source driving device and lighting system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a light source driving device and an illumination system capable of suppressing an increase in the number of input terminals of the dimming signal according to the type of dimming signal input to the light source driving device. A light source driving device includes a plurality of signal input terminals to which a dimming signal of a system selected in advance from different systems is input, and a plurality of the signal input terminals according to a switching state predetermined for each system. A switching unit that switches the selection of the output destination of the dimming signal input to the signal input terminal, a determination unit that determines the system of the input dimming signal when the output destination is selected, and the input dimming signal. Based on the determination result of the optical signal system, a dimming ratio conversion unit that converts the dimming signal value represented by the input dimming signal into a dimming ratio, and a current that drives the light source unit according to the dimming ratio. And a drive current generating unit that generates the drive current. [Selection diagram] Fig. 1

Description

  The present invention relates to a light source driving device and a lighting system.

  Examples of the method of the dimming signal in the lighting system include digital multiplex (Digital Multiplex: DMX), digital addressable lighting interface (DALI), and pulse width modulation (Pulse Width Modulation: PWM). ) Are known (see Patent Document 1).

Japanese Patent No. 6054901

  A conventional light source driving device includes an input terminal for a dimming signal for each type of a dimming signal input to the light source driving device. Therefore, the number of input terminals of the dimming signal in the light source driving device increases according to the type of the dimming signal input to the light source driving device. For example, when the types of the dimming signal are DMX, DALI, and PWM, the conventional light source driving device includes three input terminals for DMX, two input terminals for DALI, and a PWM. It is necessary to provide at least seven input terminals with two input terminals. As described above, the conventional light source driving device has a problem that the number of input terminals of the dimming signal cannot be prevented from increasing according to the type of the dimming signal input to the light source driving device. .

  In view of the above circumstances, the present invention provides a light source driving device capable of suppressing an increase in the number of input terminals of a dimming signal according to the type of a dimming signal input to the light source driving device, and It aims to provide a lighting system.

  One embodiment of the present invention provides a plurality of signal input terminals to which a dimming signal of a method selected in advance from among different methods is input, and the plurality of signals according to a switching state predetermined for each method. A switching unit for switching the selection of the output destination of the dimming signal input to the input terminal, a determining unit for determining the type of the input dimming signal when selected as the output destination, and an input dimming signal A dimming rate conversion unit that converts a dimming signal value represented by an input dimming signal into a dimming rate based on the determination result of the method, and generates a current for driving a light source unit according to the dimming rate. And a driving current generating unit.

  One embodiment of the present invention is a lighting system including a light source driving device and a light source unit, wherein the light source driving device is configured to receive a plurality of dimming signals of a method selected in advance from among different methods. A signal input terminal, a switching unit that switches selection of an output destination of the dimming signal input to the plurality of signal input terminals according to a switching state predetermined for each method, and when the output destination is selected as the output destination. A determining unit that determines the type of the input dimming signal, and converts a dimming signal value represented by the input dimming signal into a dimming rate based on the determination result of the type of the input dimming signal. A dimming rate conversion unit; and a driving current generating unit that generates a current for driving the light source unit according to the dimming rate, wherein the light source unit emits light at the dimming rate according to the current. , Lighting system.

  According to the present invention, it is possible to suppress an increase in the number of input terminals of a dimming signal according to the type of a dimming signal input to the light source driving device.

FIG. 2 is a diagram illustrating a configuration example of a lighting system according to the first embodiment. FIG. 3 is a diagram illustrating a configuration example of a switching unit and a drive control unit according to the first embodiment. FIG. 3 is a diagram illustrating a relationship example between a dimming signal value and a dimming rate in the first embodiment. FIG. 4 is a diagram illustrating a relationship example between a dimming signal value and a maximum current value in the first embodiment. FIG. 3 is a diagram illustrating a first example of a pulse current signal in the first embodiment. FIG. 5 is a diagram illustrating a second example of the pulse current signal in the first embodiment. It is a figure in the 2nd Embodiment which shows the example of composition of the lighting system. FIG. 11 is a diagram illustrating a first example of a relationship between a dimming signal value and a dimming rate in the second embodiment. FIG. 13 is a diagram illustrating a second example of the relationship between the dimming signal value and the dimming rate in the second embodiment. It is a figure in the 2nd Embodiment which shows the example of a structure of a switching part and a drive control part.

An embodiment of the present invention will be described in detail with reference to the drawings.
(1st Embodiment)
FIG. 1 is a diagram illustrating a configuration example of a lighting system 1. The illumination system 1 is a system that drives illumination (light source unit). The illumination system 1 includes a DC converter 2, a dimmer 3, a light source driving device 4, and a first light source unit 5.

  The DC converter 2 is a device that converts an input AC voltage (AC Voltage) into a DC voltage (DC Voltage). The DC converter 2 outputs a DC voltage to the light source driving device 4.

  The dimmer 3 is a device that generates a dimming signal. The dimming signal is, for example, an instruction signal in a DMX method (for example, DMX-512A), an instruction signal in a DALI method (for example, IEC62386-102), or an instruction signal in a PWM method. The dimmer 3 corresponds to at least one of the methods. The dimmer 3 outputs, to the light source driving device 4, a dimming signal of, for example, one type selected in advance from the respective types.

  The light source driving device 4 is a device that drives the light source unit. Hereinafter, a current signal having a pulse width corresponding to the pulse width control signal is referred to as a “pulse current signal”. The light source driving device 4 generates a pulse current signal for driving the light source unit based on the DC voltage input from the DC converter 2 and the dimming signal input from the dimmer 3. The light source driving device 4 outputs the generated pulse current signal to the first light source unit 5.

  The first light source unit 5 is a device that emits light, and is, for example, an LED (Light Emitting Diode). The first light source unit 5 emits light at a dimming rate according to the pulse current signal input from the light source driving device 4. The color of the first light source unit 5 is a single color, for example, a daylight color.

Next, details of each component of the lighting system 1 will be described.
The DC converter 2 includes an AC input terminal 20, a power factor improving unit 21, and a constant voltage control unit 22. An AC voltage is input to the AC input terminal 20. The AC voltage is, for example, 100 V or 200 V. The AC frequency is, for example, 50 Hz or 60 Hz. The power factor improving unit 21 improves a power factor of the input AC current. The constant voltage control unit 22 generates a constant DC voltage from the AC voltage by executing a switching process. The generated DC voltage may include an AC component.

  The light source driving device 4 includes a switching unit 40, a power detection unit 41, a drive control unit 42, a drive current generation unit 43, a DC input terminal 100, a ground terminal 101, a shield input terminal 102, a signal input terminal 103 to 104, signal output terminals 105 to 107, an anode connection terminal 108, and a cathode connection terminal 109.

  The drive control unit 42 includes a first interface 420, a second interface 421, a third interface 422, a determination unit 423, a signal generation unit 424, a lighting processing unit 425, a maximum current setting unit 426, and a storage unit. 427. Part or all of the functional units of the drive control unit 42 are realized by a processor such as a CPU (Central Processing Unit) executing a program stored in the storage unit 427. Part or all of the functional units of the drive control unit 42 may be realized using hardware such as an LSI (Large Scale Integration) or an ASIC (Application Specific Integrated Circuit).

  The drive current generator 43 (light control driver) is a functional unit that generates a current for driving the light emitting unit. The drive current generator 43 includes a constant voltage controller 430, a current detector 431, an error amplifier 432, a constant current controller 433, and a pulse width dimmer 434.

  Either a constant voltage or a DC voltage including an AC component is input from the DC converter 2 to the DC input terminal 100. The ground terminal 101 (GND) is connected to the ground terminal of the DC converter 2. The shield input terminal 102 and the signal input terminals 103 to 104 are connected to the dimmer 3. The shield input terminal 102 is connected to a shield wire (twisted wire) that protects the DMX dimming signal. To the signal input terminals 103 to 104, a signal line of one type of a DMX signal line, a DALI signal line, and a PWM signal line is connected. Thus, the signal input terminals 103 to 104 are input terminals shared by dimming signals of different systems.

  When the dimmer 3 outputs a DMX (first system) dimming signal (digital signal) to the light source driving device 4, a signal line for transmitting a DMX positive polarity dimming signal is provided at the signal input terminal 103. Connected. The signal input terminal 104 is connected to a signal line for transmitting a light control signal having a negative polarity of DMX.

  When the dimmer 3 outputs a dimming signal (digital signal) of DALI (second system) to the light source driving device 4, a dimming signal of a positive polarity (DA +) of DALI is transmitted to the signal input terminal 103. The signal line is connected. The signal input terminal 104 is connected to a signal line for transmitting a dimming signal having a DALI negative polarity (DA−). When the second interface 421 is provided with an automatic polarity reversing circuit, a signal line of a negative polarity (DA−) of DALI is connected to the signal input terminal 103, and a signal of a positive polarity (DA +) of DALI is connected to the signal input terminal 104. Wires may be connected.

  When the dimmer 3 outputs a dimming signal of PWM (third system) to the light source driving device 4, a signal line for transmitting a dimming signal of a positive polarity of PWM is connected to the signal input terminal 103. The signal input terminal 104 is connected to a signal line that transmits a PWM dimming signal having a negative polarity. When the third interface 422 is provided with an automatic polarity reversing circuit, a signal line for a PWM negative polarity dimming signal is connected to the signal input terminal 103, and a PWM positive polarity dimming signal is connected to the signal input terminal 104. A signal line may be connected.

  Inside the light source driving device 4, the signal output terminal 105 is connected to the shield input terminal 102. The signal output terminal 106 is connected to the signal input terminal 103. The signal output terminal 107 is connected to the signal input terminal 104.

  The anode connection terminal 108 outputs a pulse current signal for driving the first light source unit 5 to the anode terminal of the first light source unit 5. The cathode connection terminal 109 outputs a pulse current signal for driving the first light source unit 5 to the cathode terminal of the first light source unit 5. The duty ratio of the pulse current signal for driving the first light source unit 5 may be 100%, may be less than 100%, or may be a mixture of 100% and less than 100%.

  The switching unit 40 is, for example, a slide switch or a toggle switch. The switching state of the switching unit 40 is set in advance by the user of the light source driving device 4. The switching unit 40 converts the dimming signal input from the signal input terminals 103 to 104 into one of the first interface 420, the second interface 421, and the third interface 422 according to the setting of the switching state. Output to the output destination.

  The power detection unit 41 determines whether or not the output of the DC converter 2 is off (whether or not the voltage is 0 V) based on the voltage of the DC input terminal 100. The power detection unit 41 outputs the determination result to the drive control unit 42.

  The first interface 420 is a DMX interface. When the first interface 420 and the switching unit 40 are connected, the first interface 420 is connected to a shielded wire (twisted wire) that protects the DMX dimming signal. When the first interface 420 and the switching unit 40 are connected to the first interface 420, a DMX dimming signal is input from the switching unit 40.

  The second interface 421 is a DALI interface. When the second interface 421 is connected to the switching unit 40, a DALI dimming signal is input from the switching unit 40 to the second interface 421.

  The third interface 422 is a PWM interface. When the third interface 422 is connected to the switching unit 40, a PWM dimming signal is input to the third interface 422 from the switching unit 40.

  The determination unit 423 determines which of the DALI, DMX, and PWM the dimming signal input from the dimmer 3 to the signal input terminals 103 to 104 is. The determining unit 423 converts a dimming signal value represented by the dimming signal into a dimming rate based on the determination result of the type of the dimming signal. The dimming signal value is not limited to a value represented by a dimming signal which is a digital signal, and may be, for example, a duty ratio of a PWM dimming signal. The determining unit 423 converts the dimming signal value into a dimming rate based on, for example, a conversion data table defined in the dimming signal method.

  The signal generation unit 424 generates a signal for controlling the pulse width of the current for driving the light source unit (hereinafter, referred to as “pulse width control signal”) at a predetermined cycle based on the dimming rate acquired from the determination unit 423. I do. The signal generator 424 outputs a pulse width control signal to the pulse width dimmer 434.

  The lighting processing unit 425 determines the maximum value of the constant current output from the constant current control unit 433 to the pulse width dimming unit 434 based on the rated current specification of the first light source unit 5. The higher the current value of the current for driving the first light source unit 5 is, the higher the light emission rate of the first light source unit 5 is. The lighting processing unit 425 outputs a signal indicating the determined maximum current value (hereinafter, referred to as a “maximum current value signal”) to the maximum current setting unit 426. The maximum current setting unit 426 sets the maximum current value determined by the signal generation unit 424 in the error amplifier 432 as a reference value for constant current control.

  The storage unit 427 stores, for example, programs and dimming characteristic data (dimming curve data). The storage unit 427 is preferably, for example, a non-volatile recording medium (non-temporary recording medium) such as a flash memory. The storage unit 427 may include a volatile recording medium such as a RAM (Random Access Memory).

  The constant voltage control unit 430 is connected to a power (DC) terminal of the drive control unit 42 and a ground (GND) terminal. When a constant voltage is input to DC input terminal 100, constant voltage control section 430 acquires the input constant voltage from DC input terminal 100. When a DC voltage including an AC component is input to DC input terminal 100, constant voltage control section 430 acquires the input DC voltage from DC input terminal 100. The constant voltage control unit 430 generates a constant DC voltage that is reduced from the voltage at the DC input terminal 100 as a power supply for driving the drive control unit 42.

  The current detection unit 431 detects the current value of the constant current generated by the constant current control unit 433. The error amplifier 432 sends a signal representing the amplified value of the difference between the maximum current value set by the maximum current setting unit 426 and the current value of the constant current detected by the constant current detection unit 431 to the constant current control unit 433. Output. The constant current control unit 433 sets a constant current from a constant voltage or a DC voltage input to the DC input terminal 100 to a maximum current value set based on an output (a signal representing an amplification value) of the error amplifier 432. Generate The constant current control unit 433 outputs a constant current having the set maximum current value to the pulse width dimming unit 434.

  The pulse width dimming unit 434 generates a pulse current signal from the constant current generated by the constant current control unit 433. The pulse width dimming unit 434 generates a pulse current signal as a current for driving the light source unit. The pulse width dimming unit 434 outputs the generated pulse current signal to the first light source unit 5.

Next, a detailed configuration example of the switching unit 40 and the drive control unit 42 will be described.
FIG. 2 is a diagram illustrating a configuration example of the switching unit 40 and the drive control unit 42. The switching unit 40 includes a contact for each method of the dimming signal. 2, the switching unit 40 includes contacts 400-1 to 400-3, contacts 401-1 to 401-3, and contacts 402-1 to 402-3. The shield input terminal 102, the signal input terminal 103, and the signal input terminal 104 are connected to any one of the contacts 400 to 402 in advance according to the setting of the switching state. In FIG. 2, as an example of the setting of the switching state, the shield input terminal 102 is connected to the contact 400-1, the signal input terminal 103 is connected to the contact 400-2, and the signal input terminal 104 is connected to the contact 400-3. ing.

  The number of signal input terminals is determined, for example, according to the largest number of signal lines of dimming signals of different systems. For example, the number of signal lines of a DMX dimming signal is three (DMX shield, DMX +, DMX-), the number of signal lines of a DALI dimming signal is two (DA +, DA-), and PWM is The number of signal lines of the dimming signal is two (PWM +, PWM−). In the first embodiment, the number of terminals of the shield input terminal 102, the signal input terminal 103, and the signal input terminal 104 (= 3) is the largest signal among the number of signal lines of dimming signals of different systems. It is determined according to the number of lines (= 3).

  The drive control unit 42 includes a first interface 420, a second interface 421, a third interface 422, a determination unit 423, and a signal generation unit 424. The first interface 420, the second interface 421, and the third interface 422 are realized using, for example, a peripheral circuit (peripheral circuit) of the processor. The determination unit 423 includes a determination unit for each type of light control signal corresponding to the drive control unit 42. 2, the determining unit 423 includes a first determining unit 500, a second determining unit 501, and a third determining unit 502. The determination unit 423 further includes a dimming rate conversion unit 503. The first determination unit 500, the second determination unit 501, the third determination unit 502, and the dimming rate conversion unit 503 are realized as software function units in the determination unit 423.

  The first interface 420 is an interface that receives a DMX dimming signal. The first interface 420 outputs the DMX dimming signal input from the switching unit 40 to the first determination unit 500. The second interface 421 is an interface that receives a DALI dimming signal. The second interface 421 outputs the DALI dimming signal input from the switching unit 40 to the second determination unit 501. The third interface 422 is an interface that receives a PWM dimming signal. The third interface 422 outputs the PWM dimming signal input from the switching unit 40 to the third determination unit 502.

  The first determination unit 500 determines whether the dimming signal input to the first determination unit 500 is a DMX dimming signal based on a predetermined DMX method. When the dimming signal input to first determining section 500 is a DMX dimming signal, first determining section 500 outputs the DMX dimming signal to dimming rate conversion section 503.

  The second determination unit 501 determines whether the dimming signal input to the second determination unit 501 is a DALI dimming signal based on a predetermined DALI method. If the dimming signal input to second determining section 501 is a DALI dimming signal, second determining section 501 outputs the DALI dimming signal to dimming rate conversion section 503.

  The third determining unit 502 determines whether the dimming signal input to the third determining unit 502 is a PWM dimming signal based on a predetermined PWM method. When the dimming signal input to the third determining unit 502 is a PWM dimming signal, the third determination unit 502 outputs the PWM dimming signal to the dimming rate conversion unit 503. The order in which the first determination unit 500, the second determination unit 501, and the third determination unit 502 determine the type of the light control signal may be determined in advance.

  Due to the inconsistency between the type of the dimming signal input from the dimmer 3 and the switching state of the switching unit 40, the determination result by the first determination unit 500, the determination result by the second determination unit 501, and the third determination unit In some cases, the determination result of step 502 is negative. In this case, the determination unit 423 notifies the user of the mismatch by executing a predetermined notification function such as blinking the first light source unit 5 at a constant cycle. The operation of such a notification function is an example, and is not limited to a specific notification operation.

  Thus, the light source driving device 4 can suppress an increase in the number of input terminals of the dimming signal according to the type of the dimming signal input to the light source driving device 4. Further, the light source driving device 4 may include not only the input terminal of the dimming signal but also the same number of output terminals as the input terminals. In some cases, a plurality of light source driving devices 4 simultaneously execute the dimming control. In this case, the plurality of light source driving devices 4 are connected to each other in a daisy chain (by daisy chain) via input terminals and output terminals provided in each light source driving device 4. The dimming signal input from the input terminal provided in the first light source driving device 4 is connected to the first light source driving device 4 via the output terminal provided in the first light source driving device 4. The data is input to the second light source driving device. Accordingly, the light source driving device 4 can also suppress an increase in the number of output terminals of the dimming signal according to the type of the dimming signal input to the light source driving device 4.

  When the dimming signal input to the first determination unit 500 is a DMX dimming signal, the dimming rate conversion unit 503 acquires the DMX dimming signal from the first determination unit 500. When the dimming signal input to the second determination unit 501 is a DALI dimming signal, the dimming rate conversion unit 503 acquires the DALI dimming signal from the second determination unit 501. When the dimming signal input to the third determining unit 502 is a PWM dimming signal, the dimming rate conversion unit 503 acquires the PWM dimming signal from the third determining unit 502. The dimming rate conversion unit 503 converts a dimming signal value in the obtained dimming signal into a dimming rate. The dimming rate conversion unit 503 outputs the dimming rate as a conversion result to the signal generation unit 424.

  FIG. 3 is a diagram illustrating a relationship example (dimming characteristics) between the dimming signal value and the dimming rate. The upper part in FIG. 3 shows an example of the relationship between the dimming signal value and the dimming rate in DMX or DALI. The dimming rate may change linearly or non-linearly (for example, in a logarithmic manner) according to a change in the dimming signal value of DMX or DALI. When the dimming rate changes nonlinearly in response to a change in the dimming signal value of DMX or DALI, the smaller the value of the dimming signal value, the higher the resolution of the dimming rate may be.

  In DMX or DALI, the range of the dimming signal value that changes linearly is 1 to 255 for DMX and 1 to 254 for DALI. The dimming signal value “1” represents the dimming rate “about 0.4%”. The DMX dimming signal value “255” and the DALI dimming signal value “254” represent the dimming rate “100%”. In DMX or DALI, the range of the dimming signal value that changes nonlinearly is 1 to 255 for DMX and 1 to 254 for DALI. The dimming signal value “1” represents the dimming rate “0.1%”. The DMX dimming signal value “255” and the DALI dimming signal value “254” represent the dimming rate “100%”.

  The lower part in FIG. 3 shows an example of the relationship between the PWM dimming signal value and the dimming rate. The dimming rate may change linearly or non-linearly according to the change in the PWM dimming signal value. When the dimming rate of the PWM changes nonlinearly according to the change of the dimming signal value of the PWM, the resolution of the dimming rate may increase as the value of the dimming signal value increases. In PWM, the range of the dimming signal value (duty ratio of the dimming signal) is 0 to 100%. The larger the PWM dimming signal value, the lower the dimming rate based on the specification of the dimming signal value of the dimmer 3. When the order of correspondence between the dimming signal value (duty ratio) and the dimming rate is reversed in the specification of the dimming signal value of the dimmer 3, the dimming signal of the dimmer 3 increases as the dimming signal value increases. The dimming rate increases based on the value specification.

  FIG. 4 is a diagram illustrating a relationship example between the dimming signal value and the maximum current value. The vertical axis in the upper part of FIG. 4 indicates the dimming rate according to the dimming signal value output from the dimmer 3 to the light source driving device 4. The vertical axis in the lower part of FIG. 4 shows the dimming rate with respect to the maximum current value set in the error amplifier 432. Each horizontal axis in FIG. 4 indicates time.

  The lighting processing unit 425 determines whether the dimming signal value has changed. For example, the lighting processing unit 425 determines whether the dimming signal value at the lighting start time t1 is the same as the dimming signal value at the time t2. If the dimming signal value at time t1 is different from the dimming signal value at time t2, the lighting processing unit 425 determines that the dimmer 3 supports the fade function of the dimming signal value. If the dimming signal value at time t1 is equal to the dimming signal value at time t2, the lighting processor 425 determines that the dimmer 3 does not support the dimming signal value fade function. Note that the lighting processing unit 425 may compare the dimming signal values a plurality of times between time t1 and t2, and determine whether the dimming signal value has changed based on the comparison result. .

  The case where the dimmer 3 supports the dimming signal value fade function will be described. The dimming signal value line 600 is an example of a line representing a time change of the dimming signal value output from the dimmer 3 corresponding to the fade function of the dimming signal value. The dimmer 3 corresponding to the fade function starts the lighting of the first light source unit 5 with a dimming signal indicating a dimming signal value that changes with time from an initial dimming rate to a target dimming rate. The signal is output to the light source driving device 4 from time t1 to time t3. In FIG. 4, the light control signal value line 600 indicates the light control signal value of the light control ratio “0%” at the lighting start time t1. The light control signal value line 600 indicates a target light control signal value of, for example, a light control rate “90%” at a time t3 after the lighting start time t1. The lighting processing unit 425 determines that the dimmer 3 is compatible with the fade function of the dimming signal value, because the dimming signal value at the lighting start time t1 is different from the dimming signal value at the time t2, A maximum current value signal representing a maximum current value that changes according to the dimming signal value is generated. The dimming rate line 700 is an example of a line representing a time change of the maximum current value that changes according to the dimming signal value. When the dimmer 3 supports the dimming signal value fade function, the curve of the dimming rate line 700 is determined according to the curve of the dimming signal value line 600.

  The case where the dimmer 3 does not support the dimming signal value fade function will be described. The dimming signal value line 601 is an example of a line representing a time change of the dimming signal value output from the dimmer 3 which does not support the fade function of the dimming signal value. The dimmer 3 which does not support the dimming signal value fade function outputs a dimming signal indicating the dimming signal value of the target dimming rate from the lighting start time t1 to the time t3 of the first light source unit 5. , To the light source driving device 4. In FIG. 4, a light control signal value line 601 indicates a light control signal value at a target light control rate of, for example, “90%” at lighting start time t1, time t2, and time t3. The lighting processing unit 425 determines that the dimmer 3 does not support the fade function of the dimming signal value because the dimming signal value at the lighting start time t1 is equal to the dimming signal value at the time t2, A maximum current value signal representing a maximum current value changing at a predetermined change rate is generated. The dimming rate line 701 is an example of a line representing a time change of the maximum current value changing at the predetermined change rate. That is, the curve shape of the dimming rate line 701 is determined according to the predetermined change rate. The change rate data is stored in the storage unit 427 in advance, for example.

  When continuously changing the dimming rate according to time, the light source driving device 4 uses a pulse width control signal instead of changing the maximum current value using a maximum current value signal that is a signal for controlling the maximum current value. May be used to change the duty ratio (pulse width) of the pulse current signal.

  The case where the dimmer 3 supports the dimming signal value fade function will be described. The signal generator 424 generates a pulse control signal indicating a duty ratio (pulse width) that changes according to the dimming signal value. The dimming rate line 700 is an example of a line representing a time change of the duty ratio that changes according to the dimming signal value. When the dimmer 3 supports the dimming signal value fade function, the curve of the dimming rate line 700 (lighting curve) is determined according to the curve of the dimming signal value line 600.

  The case where the dimmer 3 does not support the dimming signal value fade function will be described. If the dimmer 3 does not support the dimming signal value fade function, the signal generator 424 generates a pulse control signal indicating a duty ratio (pulse width) that changes at a predetermined change rate. The dimming rate line 701 is an example of a line representing a time change of the maximum current value changing at the predetermined change rate. That is, the shape of the curve (lighting curve) of the dimming rate line 701 is determined according to the predetermined change rate.

  When the dimming rate is continuously changed according to time, the control result of the duty ratio (pulse width) and the control result of the maximum current value do not conflict with each other, that is, the control of the duty ratio and the maximum current value. The determination unit 423 may cause the adjustment ratio output to the signal generation unit 424 and the adjustment ratio output to the lighting processing unit 425 to be different from each other so that both of the controls are not performed. When continuously changing the dimming rate according to time, the determination unit 423 adjusts the duty ratio control result and the maximum current value control result so as not to compete with each other, while controlling the duty ratio and the maximum current value. May be executed (combined execution).

  Thereby, even when the dimmer 3 does not support the dimming signal value fade function, the light source driving device 4 continuously changes the dimming rate when the first light source unit 5 is turned on according to time. It is possible to do. Therefore, the light source driving device 4 can improve the quality of lighting of the first light source unit 5.

  The determination unit 423 and the lighting processing unit 425 may improve the quality of turning off the first light source unit 5 based on the result of determining whether the output of the DC converter 2 is off. That is, the lighting processing unit 425 sets the maximum current value at a predetermined change rate when the first light source unit 5 is turned off, even when the dimmer 3 does not support the dimming signal value fade function. It may be reduced. Similarly, the determination unit 423 may reduce the pulse width of the pulse current signal at a predetermined rate of change even when the dimmer 3 does not support the dimming signal value fade function. The light source driving device 4 controls the first light source unit 5 and the drive control so that the dimming rate of turning off the first light source unit 5 can be controlled from time t1 when the output of the DC converter 2 is turned off to time t3. A battery for driving the unit 42 may be provided.

Next, an operation example of the drive current generation unit 43 will be described.
FIG. 5 is a diagram illustrating a first example of the pulse current signal. The left side in FIG. 5 illustrates an example of the constant current output from the constant current control unit 433 to the pulse width dimming unit 434. The right side in FIG. 5 illustrates an example of a pulse current signal output from the pulse width dimming unit 434 to the first light source unit 5. The duty ratio of the pulse current signal (the pulse width of the pulse current signal) need not be 100%. In the pulse current signal, the current value of the pulse current signal is higher than the current value of the constant current output from the constant current control unit 433 for the period in which the current value of the pulse current signal is 0 A (the pulse current signal is turned off). There is a period during which the value temporarily increases. The determination unit 423 determines the duty ratio and the current value of the pulse current signal so that the effective value of the constant current output from the constant current control unit 433 is equal to the effective value of the current of the pulse current signal.

  The deciding unit 423 outputs from the constant current control unit 433 by fixing or changing and combining any of the constant current value, the current value of the pulse current signal, and the duty ratio output from the constant current control unit 433. The duty ratio and the current value of the pulse current signal may be determined so that the effective value when the constant current is changed and the effective value of the current of the pulse current signal are the same. For example, the determining unit 423 fixes the current values of the constant current and the pulse current signal output from the constant current control unit 433 to the maximum current value, and changes the constant current output from the constant current control unit 433. Only the duty ratio of the pulse current signal may be determined so that the effective value is equal to the effective value of the current of the pulse current signal.

  FIG. 6 is a diagram illustrating a second example of the pulse current signal. The vertical axis indicates the current value. The horizontal axis indicates time. A plurality of pulse current signals output in a predetermined period may be combined in accordance with a resolution (required resolution) required as a standard of the dimming rate. In FIG. 6, as an example, four pulse current signals from time t4 to time t7 are combined.

  The duty ratios of the combined pulse current signals may be different from each other. In FIG. 6, the duty ratio of the pulse current signal 200 is 0.01% as an example. The duty ratio of the pulse current signal 201 is, for example, 0.02%. The duty ratio of the pulse current signal 202 is, for example, 0.03%.

  If the duty ratio resolution of the pulse current signal is in increments of 0.01% and the duty ratios of the plurality of pulse current signals are only 0.01%, the resolution of the dimming rate is 10,000 (= 1/0. 0001) gradation. On the other hand, when four pulse current signals are combined, the resolution of the dimming rate (0 to 100%) is 40000 (= 40000) using the average of the duty ratio of the four pulse current signals. /0.0001) gradation. For example, in the second stage from the bottom in FIG. 6, the light source driving device 4 determines that the duty ratio “0.02%” of the pulse current signal 201-1 and the duty ratio “0.01%” of the pulse current signal 200-2. , The duty ratio “0.01%” of the pulse current signal 200-3, and the duty ratio “0.01%” of the pulse current signal 200-4, and these average duty ratios “0.0125”. % (= (0.02 + 3 × 0.01) / 4) ”. As described above, the light source driving device 4 can express the duty ratio “0.0025%” smaller than the duty ratio “0.01%” of the pulse current signal 200.

  Thereby, the light source driving device 4 can improve the resolution of the dimming rate. Therefore, the light source driving device 4 can realize fine and smooth dimming according to time. The light source driving device 4 can improve the resolution of the dimming rate particularly in the lower limit range of the dimming rate where the pulse width of the pulse current signal becomes narrow.

  Note that the current values of the combined pulse current signals may be different from each other. Thereby, the light source driving device 4 can further improve the resolution of the dimming rate as compared with the case where only the pulse width of each combined pulse current signal is controlled.

  As described above, the light source driving device 4 of the first embodiment includes the signal input terminals 103 to 104, the switching unit 40, each determination unit such as the first determination unit 500, the dimming rate conversion unit 503, A current generator 43. To the signal input terminals 103 to 104, a dimming signal of a method selected in advance from among different methods (DMX, DALI, PWM) is input. The switching unit 40 switches the selection of the output destination of the dimming signal input to the plurality of signal input terminals according to a switching state predetermined for each method. When each of the determination units is selected as the output destination, the determination unit determines the type of the input dimming signal. The dimming rate conversion unit 503 converts a dimming signal value represented by the input dimming signal into a dimming rate based on the determination result of the type of the input dimming signal. The drive current generation unit 43 generates a current for driving the first light source unit 5 according to the dimming rate. The light source driving device 4 may include signal output terminals 105 to 107.

  Accordingly, the light source driving device 4 of the first embodiment can suppress an increase in the number of input terminals of the dimming signal according to the type of the dimming signal input to the light source driving device 4. It is. When the light source driving device 4 includes a signal output terminal, the light source driving device 4 of the first embodiment has a number of dimming signal output terminals depending on the type of the dimming signal output from the light source driving device 4. It is possible to suppress the increase. In the light source driving device 4, the number of signal input terminals and signal output terminals is small, and the housing of the light source driving device 4 is not large. For this reason, even when the diameter of the hole provided in the ceiling where the first light source unit 5 is installed is small, the width of the housing of the light source driving device 4 is smaller than the diameter of the hole. Can be installed on the back.

(2nd Embodiment)
The second embodiment is different from the first embodiment in that a lighting system includes a first light source unit and a second light source unit. In the second embodiment, differences from the first embodiment will be described.

  FIG. 7 is a diagram illustrating a configuration example of the lighting system 1a. The illumination system 1a is a system that drives illumination (light source unit). The illumination system 1a includes a DC converter 2, a dimmer 3, a light source driving device 4a, a first light source unit 5, and a second light source unit 6.

  The light source driving device 4a is a device that drives the light source unit. The light source driving device 4 a generates a pulse current signal for driving the light source unit based on the DC voltage input from the DC converter 2 and the dimming signal input from the dimmer 3. The light source driving device 4a outputs a pulse current signal to the first light source unit 5 and the second light source unit 6.

  The light source driving device 4a includes a switching unit 40, a power detection unit 41, a drive control unit 42a, a drive current generation unit 43a, a DC input terminal 100, a ground terminal 101, a shield input terminal 102, a signal input terminal 103-104, signal output terminals 105-107, anode connection terminal 108, cathode connection terminal 109, signal input terminals 110-111, signal output terminals 112-113, anode connection terminal 114, cathode connection terminal 115. The shield input terminal 102, the signal input terminals 103 to 104, and the signal input terminals 110 to 111 are connected to the dimmer 3.

  When the dimmer 3 outputs a PWM dimming signal to the light source driving device 4, a signal line for transmitting a positive dimming signal of the PWM for dimming is connected to the signal input terminal 103. The signal input terminal 104 is connected to a signal line (for the first channel and the second channel) for transmitting a dimming signal having a negative polarity of dimming PWM. The signal input terminal 110 is connected to a signal line for transmitting a light control signal (toning signal) having a positive polarity of PWM for toning, and the signal input terminal 111 is connected to a signal having a negative polarity of PWM for toning. A signal line (for the first and second channels) for transmitting an optical signal (toning signal) is connected. When the fourth interface 428 is provided with an automatic polarity reversing circuit, a PWM dimming signal (toning signal) having a negative polarity of PWM is input to the signal input terminal 110, and a dimming signal having a positive polarity of PWM is input to the signal input terminal 111. (A toning signal).

  The signal output terminal 112 is connected to the signal input terminal 110. The signal output terminal 113 is connected to the signal input terminal 111. The anode connection terminal 114 outputs a pulse current signal for driving the second light source unit 6 to the anode terminal of the second light source unit 6. The cathode connection terminal 115 outputs a pulse current signal for driving the second light source unit 6 to the cathode terminal of the second light source unit 6. The duty ratio of the pulse current signal for driving the second light source unit 6 may be 100%, may be less than 100%, or may be a mixture of 100% and less than 100%.

  The first light source unit 5 is a device that emits light, and is, for example, an LED. The first light source unit 5 emits light at a dimming rate according to the pulse current signal input from the light source driving device 4. The color of the first light source unit 5 is a single color, for example, a daylight color. The channel of the pulse current signal for driving the first light source unit 5 is the first channel.

  The second light source unit 6 is a device that emits light, and is, for example, an LED. The second light source unit 6 emits light at a dimming rate according to the pulse current signal input from the light source driving device 4. The color of the second light source unit 6 is, for example, a bulb color. The channel of the pulse current signal that drives the second light source unit 6 is the second channel.

  The dimming signal is, for example, an instruction signal of a DMX method (for example, DMX-RDM), an instruction signal of a DALI method (for example, IEC62386-209), or an instruction signal of PWM. The dimmer 3 corresponds to at least one of the methods. The dimmer 3 converts the first channel dimming signal and the second channel dimming signal into the signal of the light source driving device 4 when one of the modes selected in advance is the DMX mode. Output to input terminals 103 and 104. The dimmer 3 outputs the dimming and toning signals to the signal input terminals 103 and 104 of the light source driving device 4 when one of the methods selected in advance is the DALI method. The dimmer 3 outputs a dimming signal to the signal input terminals 103 and 104 of the light source driving device 4 when one of the methods selected in advance is the PWM method. The dimmer 3 outputs a dimming signal for toning to the signal input terminals 110 and 111 of the light source driving device 4 when one of the systems selected in advance is the PWM system.

  FIG. 8 is a diagram illustrating a first example of the relationship between the dimming signal value and the dimming rate. The dimming rate line 800 is a curve of the dimming rate common to the first channel and the second channel. Based on the specification of the dimming signal value of the dimmer 3, as the dimming signal value (duty ratio) of the PWM dimming signal input to the signal input terminals 103 and 104 increases, the first light source unit 5 and the The dimming rate of the second light source unit 6 decreases. When the dimming signal value specifications of the dimmer 3 are opposite, the dimming rate of the first light source unit 5 and the second light source unit 6 increases as the dimming signal value increases. The dimming rate line 800 is not limited to linear, but may be non-linear.

  FIG. 9 is a diagram illustrating a second example of the relationship between the toning signal value and the dimming rate. The dimming rate line 801 is a curve of the dimming rate of the first channel. As the dimming signal value (duty ratio) of the PWM dimming signal input to the signal input terminals 110 and 111 is larger, the dimming rate of the first light source unit 5 corresponding to the first channel is lower. The dimming rate line 802 is a curve of the dimming rate of the second channel. As the dimming signal value (duty ratio) of the PWM dimming signal input to the signal input terminals 110 and 111 is larger, the dimming rate of the second light source unit 6 corresponding to the second channel is higher. The dimming rate line 801 and the dimming rate line 802 are not limited to linear, but may be non-linear.

  In FIG. 9, the sum of the dimming rate represented by the PWM dimming signal of the first channel and the dimming rate represented by the PWM dimming signal of the second channel is constant. For this reason, the total light emission amount of the first light source unit 5 and the second light source unit 6 is constant, and the emission color by the combination of the first light source unit 5 and the second light source unit 6 changes.

  The drive control unit 42a includes a first interface 420, a second interface 421, a third interface 422, a determination unit 423a, a signal generation unit 424a, a lighting processing unit 425, a maximum current setting unit 426a, and a storage unit. 427 and a fourth interface 428. Some or all of the functional units of the drive control unit 42a are realized by a processor such as a CPU executing a program stored in the storage unit 427. Part or all of the functional units of the drive control unit 42a may be implemented using, for example, hardware such as an LSI or an ASIC.

  FIG. 10 is a diagram illustrating a configuration example of the switching unit 40 and the drive control unit 42a. The third interface 422 is a PWM dimming interface. The PWM dimming signal is input to the third interface 422 from the switching unit 40. The fourth interface 428 is a PWM interface for toning. To the fourth interface 428, a PWM dimming signal is input from the signal input terminals 110 and 111.

  The determination unit 423a determines which of the DALI, DMX, and PWM the dimming signal input from the dimmer 3 to the signal input terminals 103 to 104 is. The determining unit 423a may determine whether the dimming signal input from the dimmer 3 to the signal input terminals 110 to 111 is a PWM dimming signal. The determination unit 423a includes a determination unit for each method (type) of the dimming signal corresponding to the drive control unit 42a. FIG. 10 includes a first determination unit 500, a second determination unit 501, a third determination unit 502, and a fourth determination unit 504.

  The fourth determination unit 504 determines whether the dimming signal input from the dimmer 3 to the signal input terminals 110 to 111 is a PWM dimming signal. If the dimming signal input from the dimmer 3 to the signal input terminals 110 to 111 is a PWM dimming signal, the fourth determination unit 504 converts the PWM dimming signal for toning into a dimming rate. Output to conversion section 503.

  As described above, the light source driving device 4 according to the second embodiment includes the signal input terminals 103 to 104, the signal input terminals 110 to 111, the switching unit 40, each determination unit such as the first determination unit 500, and the like. It includes a light rate conversion unit 503 and a drive current generation unit 43a. A dimming signal of a method selected in advance from among different methods (DMX, DALI, PWM) is input to the signal input terminals 103 to 104 and the signal input terminals 110 to 111. The switching unit 40 switches the selection of the output destination of the dimming signal input to the plurality of signal input terminals according to a switching state predetermined for each method. When each of the determination units is selected as the output destination, the determination unit determines the type of the input dimming signal. The dimming rate conversion unit 503 converts the dimming signal value represented by the input dimming signal into a dimming rate of the first channel and a dimming rate of the second channel based on the determination result of the type of the input dimming signal. And convert it to luminous efficiency. The driving current generation unit 43a generates a current for driving the first light source unit 5 and the second light source unit 6 according to the dimming rate. The light source driving device 4 may include signal output terminals 105 to 107 and signal output terminals 112 to 123.

  Accordingly, the light source driving device 4 of the second embodiment can control the input of the dimming signal according to the type of the dimming signal input to the light source driving device 4 even when controlling the dimming and the toning. It is possible to suppress an increase in the number of terminals. The light source driving device 4 according to the second embodiment includes a signal output terminal, and the method of the dimming signal output from the light source driving device 4 even when dimming and toning control are performed. It is possible to suppress an increase in the number of dimming signal output terminals according to the type.

  As described above, the embodiments of the present invention have been described in detail with reference to the drawings. However, the specific configuration is not limited to the embodiments and includes a design and the like within a range not departing from the gist of the present invention.

  REFERENCE SIGNS LIST 1 lighting system, 1a lighting system, 2 DC converter, 3 dimmer, 4 light source driving device, 5 first light source unit, 6 second light source unit, 20 AC input terminal, 21 Power factor improving section, 22 constant voltage control section, 40 switching section, 41 power supply detecting section, 42 drive control section, 42a drive control section, 43 drive current generation section, 43a drive current generation section, 100 ... DC input terminal, 101 ground terminal, 102 shield input terminal, 103-104 signal input terminal, 105-107 signal output terminal, 108 anode connection terminal, 109 cathode connection terminal, 110-111 signal input Terminal, 112 to 113: signal output terminal, 114: anode connection terminal, 115: cathode connection terminal, 200 to 202: pulse current signal, 400 to 402: contact, 420: first interface, Reference numeral 21: second interface, 422 ... third interface, 423 ... determination unit, 423a ... determination unit, 424 ... signal generation unit, 424a ... signal generation unit, 425 ... lighting processing unit, 426 ... maximum current setting unit, 426a ... maximum Current setting section, 427 storage section, 428 fourth interface, 430 constant voltage control section, 431 current detection section, 432 error amplifier, 433 constant current control section, 434 pulse width dimming section, 435 ... Current detecting section, 436: error amplifier, 437: constant current control section, 438: pulse width dimming section, 500: first determining section, 501: second determining section, 502: third determining section, 503: dimming rate Conversion unit, 504: fourth determination unit, 600: light control signal value line, 601: light control signal value line, 700 to 701: light control rate line, 800 to 802: light control rate line

Claims (5)

A plurality of signal input terminals to which a dimming signal of a method selected in advance from among different methods is input,
A switching unit that switches selection of an output destination of a dimming signal input to the plurality of signal input terminals, according to a switching state predetermined for each method,
When selected as the output destination, a determination unit that determines the method of the input dimming signal,
A dimming rate conversion unit that converts a dimming signal value represented by the input dimming signal into a dimming rate based on the determination result of the type of the input dimming signal,
A drive current generating unit that generates a current for driving the light source unit according to the dimming rate ,
The switching unit is a slide switch or a toggle switch,
Light source drive. A plurality of signal input terminals to which a dimming signal of a method selected in advance from among different methods is input,
A switching unit that switches selection of an output destination of a dimming signal input to the plurality of signal input terminals, according to a switching state predetermined for each method,
When selected as the output destination, a determination unit that determines the method of the input dimming signal,
A dimming rate conversion unit that converts a dimming signal value represented by the input dimming signal into a dimming rate based on the determination result of the type of the input dimming signal,
A drive current generating unit that generates a current for driving the light source unit according to the dimming rate ,
The apparatus further includes a plurality of signal output terminals that output the dimming signals input to the plurality of signal input terminals,
Light source drive. The method is a digital multiplex, a digital addressable writing interface, and any of pulse width modulation,
The light source driving device according to claim 1. A lighting system including a light source driving device and a light source unit,
The light source driving device,
A plurality of signal input terminals to which a dimming signal of a method selected in advance from among different methods is input,
A switching unit that switches selection of an output destination of a dimming signal input to the plurality of signal input terminals according to a switching state predetermined for each method,
When selected as the output destination, a determination unit that determines the method of the input dimming signal,
A dimming rate conversion unit that converts a dimming signal value represented by the input dimming signal into a dimming rate based on the determination result of the type of the input dimming signal,
A drive current generating unit that generates a current for driving the light source unit according to the dimming rate,
The switching unit is a slide switch or a toggle switch,
The light source unit emits light at the dimming rate according to the current,
Lighting system. A lighting system including a light source driving device and a light source unit,
The light source driving device,
A plurality of signal input terminals to which a dimming signal of a method selected in advance from among different methods is input,
A switching unit that switches selection of an output destination of a dimming signal input to the plurality of signal input terminals according to a switching state predetermined for each method,
When selected as the output destination, a determination unit that determines the type of the input dimming signal,
A dimming rate conversion unit that converts a dimming signal value represented by the input dimming signal into a dimming rate based on the determination result of the type of the input dimming signal,
A drive current generating unit that generates a current for driving the light source unit according to the dimming rate,
Further comprising a plurality of signal output terminals for outputting the dimming signal input to the plurality of signal input terminals,
The light source unit emits light at the dimming rate according to the current,
Lighting system.

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